System and method for improving resolution of channel data

ABSTRACT

Disclosed are methods for processing distribution channel data integrating business information with geographic data to produce integrated data, wherein the integrated data has greater resolution than the business information. Distribution channel data is captured and correlated with the integrated data to increase the resolution of the distribution channel data.

The present invention claims priority from, and is a continuation application of, U.S. patent application Ser. No. 11/948,743 filed Nov. 30, 2007 and issued as U.S. Pat. No. 7,644,070 on Jan. 5, 2010, which is a continuation of, U.S. patent application Ser. No. 10/670,545 filed Sep. 24, 2003 and issued as U.S. Pat. No. 7,324,987 on Jan. 29, 2008, which is related to, and claims benefit of U.S. Provisional Patent Application Ser. No. 60/420,712 filed Oct. 23, 2002, all of which are incorporated herein by reference in their entirety.

The disclosures of the foregoing applications are herein specifically incorporated by this reference in their entirety. The present invention claims the benefit of U.S. Provisional Application Field of the Invention.

BACKGROUND OF THE INVENTION

1. Prior Application

The present invention relates, in general, to distribution and sales channel management for goods and services and, more particularly, to software, systems and methods for improving the resolution and usefulness of data related to direct and indirect sales channel participants and activities used for channel management.

2. Relevant Background

Efficient distribution of products is fundamental to an effective economy. As used herein, “products” include both goods and services. In many cases, distribution makes up a significant if not majority portion of the final cost. Hence, efficient distribution leads to higher profits and lower consumer prices. Moreover, efficient distribution tends to lead to higher consumer satisfaction and greatly reduced waste of resources, time, and money used to distribute the products. Various alternative distribution channels have been implemented to address the limitations of the retail channel. In direct sales channel a supplier creates their own marketplace and sells directly to the consumer. This gives the supplier a great deal of control and promises to reduce distribution costs. However, direct sales are a poor substitute when the marketing costs of reaching consumers and drawing them into the marketplace are sizable. As a result, the marketplace created by direct sales channels tends to be orders of magnitude smaller than the marketplace created by distribution channels.

Both consumers and businesses purchase products through distribution channels. Business-to-consumer channels and business-to-business channels are similar with the notable exception that business-to-business channels typically lack a retail outlet where goods/services are exchanged directly with a purchaser. In addition, business-to-business transactions often require a higher level of expertise and increased interaction between the seller and buyer. As a result, business-to-business channel participants rely more heavily on an efficient and accurate distribution channel. In both cases, however, many channel participants such as the producer, sales personnel, distributors, and the like may lose visibility of the activities of other participants. For example, it remains difficult for a manufacturer or producer to obtain information about the purchaser when a product is delivered to a post office box, loading dock, or first to a channel partner, who in turn delivers the products or services to a customer at a later time. After the initial transaction, the producer loses visibility of important distribution channel details.

The process of distribution generally involves actions taken to get products into a relevant marketplace where a consumer or end user makes a purchase decision. Sales and marketing personnel often initiate a transaction by taking and scheduling customer orders for goods and services. Production, stocking, product movement, and shipping activities occur to fulfill orders, but these activities often occur independently and in anticipation of orders. Hence, an order may be fulfilled by a shipment from any of a number of warehouse locations, and a salesperson or producer must rely on information from the distribution site to know where, when, and how order fulfillment occurs. Distribution channels may be multiple-tier (e.g., distributors and resellers) and, as a result, further obscure information relating to the end-customer from other channel participants.

At the same time, a customer may have several apparent identities. Many businesses operate under several names, or names that are abbreviated in different ways, and so will appear as different businesses to a distribution channel. Frequently, a business will have multiple delivery addresses either for different locations, or to implement internal distribution channels. For example, a corporate headquarter's address may have little or no relation to a loading dock address used for deliveries, or a post office box address used for customer returns. As a result, a salesperson may be dealing with one business apparent identity while a shipper or warehouse is dealing with a separate apparent identity. Hence, it may be difficult to match captured information to information used by sales/marketing personnel, producers, and other channel participants.

Because the distribution chain may obscure some data about the end-customer, the supplier loses a great deal of information related to buyer behavior. For example, a direct sales person responsible for an account may be unaware of sales made to a subsidiary of the customer that uses a different name, or is at a different address than the main account address known to the sales person. Such information would be useful to manage sales representative compensation, future production, product design, and marketing efforts, as well as to determine sales achievement levels for various organizational entities to determine whether business objectives were met. Hence, suppliers share the desire for product distribution solutions that make precise data about distribution chain events available to interested parties.

SUMMARY OF THE INVENTION

Briefly stated, the present invention involves a system for managing a product distribution channel involving a plurality of participants acting as producers, consumers, and conduits for the distribution channel. At least one of the plurality of participants is imprecisely identified. Spatial information records are combined with captured channel information to specifically identify the channel participant who is imprecisely identified.

In another aspect, the present invention involves a method for gathering data from a distribution channel in which a transaction record related to a distribution channel event is generated. The transaction record comprises transaction data identifying at least one channel participant. The transaction record is processed by geocoding location data within the transaction data to determine a spatial identifier for the transaction record. A reference record database is accessed using the spatial identifier to identify one or more reference records having spatial data that is similar to the spatial identifier associated with the transaction record.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows information relationship in a distribution environment in which the present invention is implemented;

FIG. 2 illustrates exemplary data records suitable for processing in accordance with the present invention;

FIG. 3 shows a functional block diagram of an information resolver according to an embodiment of the present invention; and

FIG. 4 illustrates relationships in a matching process in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention provides, among other things, a system and method that enables customer or channel participant “roll-up” for accounting and aggregation purposes. Although a significant focus is to provide channel information with greater precision and granularity, it should be appreciated that such precision enables one to aggregate channel information with greater accuracy to manage information with less granularity. This allows transactions to be identified with higher-level organizations (through business rules) that can be determined through relationships in the business information reference data.

The greater precision allows for clustering of business information by any organizational node in a corporate tree identified through reference database relationships. The present invention provides for clustering/association/aggregation of transactions based on common business identities at any level of a tree, for the purposes of sales aggregation, behavior analysis, product traffic analysis, etc.

FIG. 1 illustrates information relationships in an exemplary distribution system that supports product distribution from a producer/manufacture 101 to various customers 102. Transaction information, designated by an encircled “i” in FIG. 1, comprises various types of information captured by channel participants such as resellers 103 and distributors 104. Although not illustrated, channel information may be captured directly by producer/manufacturer 101 themselves in which case the data resolution enhancement processes and mechanisms, in accordance with the present invention, may be implemented by producer/manufacturer 101 internally.

Transaction information may comprise electronic data interchange (EDI) messages, flat files of a standardized or proprietary format, database records, spreadsheets, XML records, or other available format for communicating information about transactions. The transaction records contain some identification of the customer name, and some locality or location information, as well as implementation specific information (e.g., model number, sub-account information, pricing, etc.) about one or more transactions that are associated with the transaction record. Significantly, the present invention does not require that the customer name and/or location information be entirely accurate or high in precision. One feature of the present invention is an ability to compensate for common errors and deficiencies in the transaction record by improving the resolution of the data as described below.

Some of the difficulties encountered in channel information capture include improper and inconsistent coding or formatting. For example, in electronic data interchange (EDI) systems a common difficulty is that state abbreviations appear in a postal code field. EDI records may lack “sell-from” information, invoice dates, and the like. The nature of this data thus makes it difficult to match the EDI record with other records maintained by channel participants such as sales records attributed to a particular market segment or sales person. Also, many distributors 104 and resellers 103 may use a single customer identification for multiple customer locations, which again makes the records difficult to match with other channel information. A large percentage of records have systematic errors introduced by coding procedures and/or typographical errors introduced by data entry personnel.

Other errors include incorrect sold-to names that identify an individual at a business rather than the business itself, or identify a subsidiary or other business related to the customer. Business names are often entered in a very inconsistent manner with abbreviations, department names/numbers, truncation, and other techniques used that may be convenient to a particular channel participant (e.g., a delivery person) but make the records difficult to interpret and match to other channel information.

FIG. 2 illustrates common errors in channel information records that make precise identification of a customer difficult. Similar errors occur in identifying other channel participants such as resellers 103 and distributors 104. FIG. 2 illustrates this with transaction records involving educational institutions. Each line item in FIG. 2 represents an exemplary transaction record, although the form and content of transaction records is expected to vary widely. The first transaction record involves The Johns Hopkins University. However, because all of the records suffer a systemic error in that the letter “s” was replaced with the letter “x”, the entity name is uncertain. Moreover, the address indicates a particular branch of the university, and does not correspond to the administrative or business address. In accordance with the present invention, these deficiencies are overcome by using the location information (e.g., address, postal code, city/state information and the like) to select one or more reference records from a database of known information. This spatial matching using location information may identify one or several business entities in the area. Lexical matching against this relatively small subset of candidate businesses will likely identify a single reference record associated with The Johns Hopkins University Hospital, which is the business identity that is in fact involved in the transaction represented by the transaction record in FIG. 2.

In the second transaction record in FIG. 2, in addition to the systemic typographical error, the business name is identified as a department, with the institution name (i.e., Arizona State University) abbreviated. This record is further confused by the placement of the state code in the postal code field, which is a common error. Again, the present invention uses the available location information to select candidate businesses and then can use lexical matching to narrow the candidate businesses to one or a very few businesses with a high probability of being a proper match. The third record illustrates a transaction record in which the ship-to address is missing completely, while the final record illustrates a situation in which the business name itself is truncated to a degree that it, at best, ambiguously identifies the channel participant.

Returning to FIG. 1, gateway 106 provides a mechanism for communicating channel data to resolver 105. Gateway 106 may comprise a special-purpose gateway processor such as an EDI gateway machine or a more general purpose mechanism such as a file transfer protocol (“FTP”) directory that is monitored by resolver 105. In other alternatives, gateway 106 comprises a web site where data can be entered or off-loaded using any available data transfer technique. Gateway 106 may receive data as files, XML documents, electronic mail, or other message format.

The present invention involves a resolver 105, which may be implemented in hardware, software, or hybrid systems, that processes transaction records to specifically identify the customers, distributors, resellers, or other participants that are imprecisely identified by the transaction record. An imprecisely identified participant means that through error or design, the transaction record cannot be matched with certainty to a known business entity. This uncertainty may be caused, for example, by typographical errors in the record, use of a trade name or trademark rather than the business entity name, inaccurate or missing address data, and the like. It is not necessary that all transaction records be imprecise because so long as even a small percentage of records are imprecise, the record cannot be used by itself to reliably identify the participant. In other words, even a low percentage of imprecise transaction records casts doubt on the veracity of all of the transaction records, even those transaction records that specify the associated business entity exactly and accurately.

Resolver 105 receives transaction records and parses the records to identify business name information. Resolver 105 also identifies the location information within a transaction record. Resolver 105 implements several processes alone or in combination with each other to improve resolution of the transaction record. These processes include 1) geocoding the location information from a transaction record; 2) using the geocode information to identify or select one or more candidate reference records from a pre-established reference record database; 3) lexical processing of business name and/or address information obtained from a transaction record; and 4) matching the transaction record to a reference record database. In this manner, the present invention uses both spatial analysis/matching and lexical analysis/matching to create an association between a transaction record (which may contain errors) to reference records (which presumably contain fewer errors and higher resolution).

In many cases the processes performed by resolver 105, shown in greater detail in FIG. 3, cooperate to identify and select a single candidate reference record that can be matched to the transaction record. However, it is recognized that it is not always possible to automatically resolve an ambiguous or erroneous transaction record to a single reference record. Accordingly, it may be necessary for subsequent automatic and/or manual processes to be engaged to finally select a single reference record or otherwise improve the resolution of the transaction record to a satisfactory level. In this manner, the present invention will operate to either automate or assist in the process of matching transaction records to reference records.

The geocoding process may be implemented by a process or series of processes that transform data that indicates a real-world geographic location to a code or value (e.g., latitude/longitude) that is representative of that real-world geographic location. Hence, a street address can be transformed by a variety of algorithmic and look-up table methods into a latitude/longitude associated with that address. Similarly, a zip code, phone number, city, state, and other information can be transformed into a geocode value. The geocoding process does not have to generate a specific point location as it may define a zone of locations of any size and shape around a particular set of location information. Hence, while the examples herein suggest using a street-level accuracy for the geocoding process, it is contemplated that in some applications the accuracy may be defined to a zip-code-level, neighborhood-level, or city-level and still be useful in accordance with the present invention.

It should be noted that the reference records include location information such as geocodes as well. Unlike conventional raw business data that may be obtained, for example, from Dun and Bradstreet or other business information providers, a reference record is processed to associate a geocode (or a zone defined by a pattern of geocodes) with the business data. Even where the business data includes some location information such as an address, or even a latitude/longitude, it may be desirable to process the provided information such that each record is associated with reliable, accurate location information As both the transaction record and reference record are associated with geocodes, the geocode can be used to link a transaction code to one or more reference records. For example, when a spatial zone is associated with the reference record, a search of reference records to obtain a list of reference records in which the geocode of the transaction record falls within the zone of a reference record may be used.

In cases where the geocode matching described above results in more than one reference record match, the present invention further contemplates lexical matching of information in the transaction record to business information in the reference record to further refine the set of reference records. Lexical matching refers to any of a variety of matching techniques that leverage knowledge of the rules, syntax, and content expected in a particular data type. For example, lexical matching of company names can take advantage of knowledge of common company abbreviations and acronyms such as “Inc.”, “Corp.”, “Ltd.”, “LLP”, and the like to provide more accurate matching. Similarly, common abbreviations and errors (e.g., using a trademark instead of a business name) can be used in the matching process. Essentially, a lexical match involves determining a score that quantifies the degree to which two strings or values match each other. Potential matches can be sorted by score, and potential matches with sufficiently high scores can be deemed matches for purposes of further processing.

For example, in a transaction involving a business entity named “MallMart, Inc.”, a transaction record might indicate a business name of MALL MART; MallMart, Inc.; MM Inc.; MMI; or the like. Other transaction records might indicate “The Photoshop at MallMart”, which should also be associated with Mallmart, Inc. At the same time, some unrelated records may exist such as a transaction identifying “Mall Drugs” where the unrelated transaction records may or may not be in the same geographic area as MallMart, Inc. In these cases, spatial matching in accordance with the present invention will identify matches for all businesses that are located at a similar address (e.g., a Nordstrom's, a Cookie Hut, or any other business) as well as a record for the target company “MallMart, Inc.”. Various lexical techniques can be used to score the similarity of “MALL MART”, “MM Inc.”, and “MMI” against the multiple candidate reference records to specifically identify the “MallMart, Inc.” reference record, while at the same time discarding any reference to Mall Drugs, even if this business is located geographically close to MallMart, Inc. Lexical matching can provide much more sophisticated processing to compensate for common spelling or coding errors as well as systemic errors in entering the names in the transaction records. Even so, it is expected that in some cases an entirely automated identification will not be possible, and a human operator will be required to identify or discard matches for some records, although this task will be greatly simplified.

FIG. 3 illustrates resolver processes 105 in greater detail. Essentially, resolver 105 receives transaction records (labeled “T-RECORD” in FIG. 3) such as EDI records, point of sale (“POS”) flat files, or other format transaction records from the client gateway 106 using any available data transport processes 301 such as FTP or web upload in the particular example. Data may be physically transported (e.g., by magnetic/optical tape, magnetic/optical disk, etc.), and/or may use any available network protocol. In particular implementations, transaction records are validated and parsed in component 303 to extract information that will be used for the matching process in accordance with the present invention.

In some embodiments of the present invention, a domain-specific or customer-specific learning process is employed by component 305 to continually improve matching as shown in FIG. 3. A learning database 307 is used to store records related to specific learned matches, and is searched using the transaction information in a manner akin to other database searches taught by this specification. The learning database is populated with information obtained whenever a high-confidence match is made either automatically by participant identification processes 309 or manually by manual identification processes 311. In this manner a system can be configured to continually learn from instances where the automated processes 309 resolved a transaction with a high degree of confidence, or did not resolve a transaction record with sufficient precision and so matching was referred to manual identification processes 311. For example, when a channel participant operates under a trade name that bears little relation to the business name, manual intervention may be required with or without the assistance of end-user, partner, and product exception resolution tools 312. Using the learning database 307, a record can be created that creates an association between the trade name and the business name, thereby enabling subsequent occurrences of the trade name to be automatically processed by participant identification processes 309 and manual operations 311/312 to be avoided.

The processes for developing a learning database 307 involve, for example, learning particular abbreviations, common misspellings, product names, trade names, and other implementation specific information that causes difficulty in precisely identifying a channel participant from a transaction record. The algorithms compensate for domain-specific, company specific, and/or systemic difficulties in transaction records thereby increasing the reliability of the downstream matching processes. These algorithms can be implemented quite flexibly, or omitted altogether, to meet the needs of a particular application.

In the particular example, when attempting to resolve a new transaction, processes 305 use the learning database 307 before either automatic or manual resolution processes so that knowledge from previously identified transactions is reused. While the overall representation of customers and other transaction entities is highly fragmented and disparate across participants, any given participant does tend to repeat the information associated with a given entity the same way in successive transactions. In one embodiment, learning database 307 is essentially subdivided to keep track of previously learned/identified patterns on a per-participant basis, or on a group of participants, or other rational sub-division that limits the scope of the pattern recognition to be within a particular group of reports only. In this way, a conservative algorithm that avoids false matches is implemented to reuse past identifications for all transactions going forward in an efficient manner.

Learning database 307 can have both exact match patterns and regular expressions mapped into its records. Therefore it is useful in identifying not only data items that have been entered into a partner's Enterprise Resource Planning (“ERP”) system correctly, but also data items that have been entered incorrectly. For example, if the company US Reprographics was entered into a partner system as US Repreographix, it would likely go through a manual process to confirm when that data item was first encountered. In addition to identifying it with the right company, a record would be entered into learning database 307 that would automatically identify the same misspelled entity and the same address in the future as the correct entity. Learning database 307 can also be used to perform broader matching using regular expressions where needed. For example, any transaction with “Taco Bell” as the only words (using any spelling or other punctuation) would be directly mapped to a specific entity.

In a particular implementation there is also a process in place to allow self-pruning of learning database 307. Since the learning database 307 serves as a lookup, it is undesirable for entries to go out of date relative to the business mapping (e.g., to a Data Universal Numbering System (“DUNS”) number). For example, when a first company acquires a second company the learning database may require adjustment to purge stored knowledge. The present invention contemplates algorithms that operate periodically or occasionally to “clean out” learning table 307 for a given business when any part of its business tree changes (e.g. if it is involved in a merger or acquisition), or if the business state changes (business goes out of business, etc.). It is thought to be better to flush any potentially affected learning records and have the next instance of the entity go back through the manual process rather than try to do anything automatically since often in M&A activity, brand names may be consolidated, split, or even sold off, which may make prior learning on these records obsolete. However, automated processes may be useful in some circumstances to adapt learned matches in a manner that adapts to the change in business state.

Participant identification component 309 includes end-customer identification processes, partner identification, and other participant identification that involve the use of location information from the transaction records to select one or more reference records such as business information records 313 (e.g., from a Dun & Bradstreet (“D&B”) database), customer-managed data such as a partner profile database 315, or the like. In particular implementations, text or other matching processes 319 are used to correct/validate the transaction-specific information in a transaction record by referencing customer product catalogs, pricing, or similar data 317. While these processes further resolve the transaction records in the spirit of the present invention, they do not directly involve the combination of spatial information in most cases. The result of the various processes shown in FIG. 4 is the matching of one, and in some cases more than one, reference record to the transaction record being processed.

The present invention may be better understood with reference to a particular example shown in FIG. 4. This example contains many specific features that are not to be construed as limitations of the broader invention, however, the specifics are useful in improving understanding of the invention.

In this example, a Transaction Record 401 is defined by the following attributes:

Name,

Street1,

Street2,

City,

State/Province,

Country, and

Telephone number

In this example, a Reference Database consists of one or more Reference Record (e.g., D&B database). A Reference Record 403 is defined by: (e.g. A record for a DUNS number)

Unique Reference Identifier (e.g., DUNS number),

Name (e.g., Business Name for the DUNS number. There might be more than one name given a Reference Number, such as tradestyle, DBA . . . etc.),

Street1,

Street2,

City,

State/Province,

Country,

Telephone,

Latitude, and

Longitude (Latitude and Longitude are, in this example, at street level (i.e., accuracy down to the building)).

An exemplary decision process involves:

1. Given a Transaction Record 401 Using Street1, Street2, City, State/Province, and Country field to find a geo-location. When it is possible to geocode the address information to a desired resolution (e.g., street level), the geocode is retained. Otherwise, the geocode failed. 2. When the geocode for the transaction record is determined, use the geocode to select a list of candidates from the Reference Database so that each candidate has a matching latitude and longitude as the transaction record. 3. When there is only one candidate, perform lexical matching using name of the transaction record with all the name variation of the candidate. Lexical based name matching first standardizes the name (such as standardizing common abbreviations (e.g., INC., LLP . . . etc), removing words that do not help in discrimination (e.g., and, or . . . etc), standardizing common business abbreviations (e.g., P&G = Proctor and Gamble . . . etc)). Once the names are standardized, a score is computed based on the similarity using an algorithm similar to dynamic programming. When the best score is greater than some pre-defined threshold, assign the candidate's reference number to the transaction record, and consider the transaction record to be matched. 4. When more than one candidate is returned from step 2, perform the lexical matching on the names as defined in step 3 between the transaction record and all the candidates. In addition, attempt to find other identifiers in the street record to match the Suite/Floor information to help identify the correct candidate. When the best score is greater than some pre-defined threshold, assign the reference number of the candidate with the best score to the transaction record, and consider the transaction record to be matched. 5. When a match is not found in Step 3 or Step 4, and there is a valid geocode, retrieve a list of candidates from the Reference database within a pre-defined radius of the Transaction record's geocode value. Perform the lexical matching on the names as defined in step 3 between the transaction record and all the candidates. When the best score is greater than some pre-defined threshold, assign the reference number of the candidate with the best score to the transaction record, and consider the transaction record to be matched. 6. When a match is not found in Step 5, try other combinations; this is because, often times, the data is not filled correctly in the transaction record. For example, when the name is placed in the street 1 field and the address is placed in the street 2 field. In this case, swap the fields and return to Steps 2-5. 7. When there are no matches found after Step 6, use supplementary algorithms and/or manual matching processes.

The reference record database includes a plurality of reference records 403 where each record corresponds to, for example, a business entity such as a customer, reseller, distributor, or the like. The reference record 403 contains precise information about the associated business entity including precise address information and any other information that can be used by one or more of the distribution channel participants. For example, a reference record may contain a sales person ID to specifically identify a sales person that should be credited for a particular transaction. Significantly, the reference records contain sufficient precision to satisfy the needs of the channel participants.

The present invention is specifically illustrated in terms of distribution channels. However, the invention is readily applied to any hierarchical business relationship and not limited to channel relationships. Although the present invention is readily implemented in automated systems, it is contemplated that various operations and actions may be performed manually or semi-automatically to meet the needs of a particular application. For example, a human being may be familiar with selecting from a list of candidates to identify suitable matches for a particular transaction record as well as this matching being implemented in an automatic/algorithmic manner such that matches exceeding a certain score or meeting some acceptable pattern of scores provide a basis for a match. Although the invention has been described and illustrated with a certain degree of particularity, it is understood that the present disclosure has been made only by way of example and that numerous changes in the combination and arrangement of parts can be resorted to by those skilled in the art without departing from the spirit and scope of the invention, as hereinafter claimed. 

1. A system for managed product distribution, comprising: one or more reference record databases, each data base having a plurality of reference records with each reference record regarding a product providing an association between business information and geo-coded spatial data; transaction data including geo-coded spatial data; a processor operable to match reference records from one of the reference record databases with transaction data and to perform lexical matching; a set of matched records created from matching one or more reference records from one of the reference record databases with the transaction data using geo-coded spatial data; one or more candidate reference records identified using lexical matching process from the set of matched records as having an association between business information and transaction data, wherein the one or more identified candidate reference records is associated with the transaction data using a unique identifier; and a memory operable to store the unique identifier.
 2. The system of claim 1 further comprising a geo-coding mechanism operable to determine street-level spatial data from the transaction data.
 3. The system of claim 1 further comprising a candidate identification mechanism operable to match one or more reference records with the transaction data using geo-coded spatial data.
 4. The system of claim 3 wherein the candidate identification mechanism determines postal code information from the transaction data.
 5. The system of claim 3 wherein the candidate identification mechanism determines location information from the transaction data.
 6. The system of claim 5 wherein the candidate identification mechanism further comprises a selection mechanism for retrieving records that have spatial data matching the spatial data obtained from the transaction record.
 7. The system of claim 1 wherein the lexical matching process is operable to correlate non-spatial data in the transaction record with non-spatial data in the candidate reference records.
 8. The system of claim 1 wherein the lexical matching process is operable to correlate spatial data in the transaction record with spatial data in the candidate reference records.
 9. A method for identifying participants in a distribution channel, comprising: receiving a transaction record comprising business and spatial data that identifies at least one channel participant, wherein the spatial data is geo-coded; accessing a reference record database, said reference record database comprising a plurality of reference records wherein each reference record comprises business and geo-coded spatial information; conducting by a processor a lexical comparison of the transaction record to the plurality of reference records to identify one or more lexical matches; comparing by said processor geo-coded spatial data of the reference record to geo-coded spatial information of the one or more lexical matches identifying at least one match between the transaction record and the plurality of reference records wherein the at least one match is associated with a unique identifier; and storing in a memory the unique identifier.
 10. The method of claim 9 wherein the at least one channel participant is an end customer.
 11. The method of claim 10 further comprising: using the one or more reference records to attribute transactions to another channel participant, wherein the transaction record itself has insufficient precision to accurately attribute the transactions and wherein the reference record database is updated based on attributing transactions to another channel participant. 